Cellular and Molecular Mechanisms Underlying Acute Quadriplegic Myopathy : Studies in Experimental Animal Models and Intensive Care Unit Patients

Norman, Holly

January 2006

<p>The combination of a severe systemic illness, corticosteroids, and neuromuscular blocking agents in patients on the mechanical ventilator often results in a condition known as Acute Quadriplegic Myopathy (AQM). While severe weakness of all spinal nerve innervated muscles is known to be a significant clinical characteristic of the disease, this symptom is typically not recognized until the disease has progressed to an advanced stage. End result effects have been classified, which include the loss of the thick filament, or myosin heavy chain, an in-excitable muscle membrane, and an up-regulation of protein degradation; however, there is little known about the acute stage of AQM. This project has focused on understanding the underlying mechanisms of AQM, specifically in regard to protein synthesis, both at the mRNA and nuclear transcription levels. To study the early stages of the disease two animal models have been developed: rat and pig. Further, we have examined AQM muscle tissue, to investigate the similarities of our animal models to patients, as well as to study the recovery process. Particular interest was directed on the myofibrillar proteins myosin (MyHC) and actin, as they are the primary proteins involved in muscle contraction, as well as the myosin associated proteins, myosin binding protein C and H. </p><p>At the mRNA level, MyHC and actin are both down-regulated in response to AQM. The myosin binding proteins are affected differently, with H protein increasing during severe atrophy and C protein either being slightly down-regulated or unchanged. Nuclear transcription factors were also affected, with such factors as MuRF1 and MAFbx up-regulated. </p><p>Thus far results have shown that protein synthesis is altered in AQM and largely contributes to both the development and recovery of the disease. The pathways of protein synthesis may prove to be an ideal target for the prevention of AQM and/or symptom alleviation.</p>

Neurosciences

Acute Quadriplegic Myopathy

intensive care unit

atrophy

myosin heavy chain

actin

myosin binding proteins

nuclear transcription factors

mRNA

Neurovetenskap

Muscle function in Juvenile Idiopathic Arthritis : A two-year follow-up

Lindehammar, Hans

January 2004

This is a study of muscle function in Juvenile Idiopathic Arthritis (JIA). Rheumatoid arthritis (RA) is a disease that primarily affects the synovial membrane of joints. Muscle weakness, atrophy and pain occur in adult RA. This may be a consequence of joint pain, stiffness and immobility. Muscle inflammation and neuropathy occur as complications in adults. Muscle function in JIA has been much less studied. The aim of the study was to examine whether muscle weakness and atrophy also occur in children with JIA. This was a longitudinal study over a two-year period, where muscle strength and thickness were measured repeatedly in a group of 20 children and teenagers with JIA. Muscle strength was measured using different methods and in several muscle groups. Muscle biopsies were obtained and nerve conduction velocity studies performed. The study concludes that, compared to healthy people, children and teenagers with JIA have as a group reduced muscle strength and muscle thickness. For most of these children and teenagers, muscle strength is only slightly lower than expected, but a few have marked muscle weakness. This is most apparent in patients with severe polyarthritis where the weakness seems to be widespread. Patients with isolated arthritis may also have greatly reduced strength and thickness of muscles near the inflamed joint. There is a risk of decreasing strength in patients with polyarthritis and in muscles near an active arthritis. Minor changes are common in muscle biopsies, and findings may indicate immunological activity in the muscles. Atrophy of type II fibres, as in adult RA, was not found in JIA. No patient had signs of neuropathy. / On the day of the public defence the status of article IV was: Submitted.

arthritis

juvenile rheumatoid

physiopathology

muscle

skeletal

pathology

physiopathology

Muscular atrophy

etiology

physiopathology

arthritis

juvenile rheumatoid

complications

Medicine

Medicin

Telomeres and the brain : an investigation into the relationships of leukocyte telomere length with functional and structural attributes of the brain / Telomerer och hjärnan : en undersökning av sambanden mellan leukocyt-telomerlängd och funktionella och strukturella egenskaper hos hjärnan

Wikgren, Mikael

January 2011

Telomeres are the outermost parts of linear chromosomes. They consist of tandemly repeated non-coding short nucleotide sequences (TTAGGG in all vertebrates), in humans spanning over the last 2 to 15 kilobase pairs of the chromosome. Due to the end-replication problem, telomeres shorten with each cellular division. A critically short telomere will trigger the cell to enter a state of cellular senescence or to apoptose. The rate of telomere shortening can be accelerated by factors such as oxidative stress and inflammation. Taken together, this contributed to making telomere length a candidate biomarker of health and aging. Studies have shown that leukocyte telomere length progressively shortens with age, and that it independent of age is associated with age-related morbidity, lifestyle factors, and mortality. This thesis was aimed at exploring the relationships of leukocyte telomere length with various functional and structural attributes of the brain. In Paper I, telomere length was shown to be longer among non-demented carriers of the apolipoprotein E (APOE) ε4 allele, a well-established risk factor for Alzheimer’s disease. However, the rate of telomere shortening was greater among the ε4 carriers, possibly due to the higher levels of oxidative stress and inflammation associated with this allele. Furthermore, performance on episodic memory tests was inversely related to telomere length among ε4 carriers. The results may contribute to a better understanding of the pathophysiology related to the APOE ε4 allele. The volume of the hippocampus, a structure in the brain critical for episodic memory function, was in Paper II found to be inversely related to telomere length among non-demented APOE ε3/ε3 carriers. No correlation between hippocampal volume and telomere length was discernible among ε4 carriers, but they fit the pattern exhibited by the ε3/ε3 carriers as they tended to have smaller hippocampi and longer telomere length compared with the ε3/ε3 carriers. The results are possibly explained by a low proliferative activity among subjects with smaller hippocampi, which might also explain the inverse association between telomere length and episodic memory performance in Paper I. In Paper III, we describe results corroborating earlier findings of shorter telomere length among individuals suffering from depression. Moreover, we found that the shorter telomere length among the patients to a large extent could be linked to a hypocortisolemic state; a state which has been associated with chronic stress. The findings corroborate the link between telomere length and stress, and underline the role of stress in depressive illness. Two prominent manifestations of the aging brain are atrophy and white matter hyperintensities. In Paper IV, we report that white matter hyperintensities and cerebral subcortical atrophy were associated with shorter telomere length in aged non-demented individuals. Cortical atrophy was not associated with telomere length. Inflammation may be the underlying cause of the associations, as it is linked to telomere attrition, subcortical atrophy, and white matter hyperintensities. Taken together, these results show that leukocyte telomere length has the potential of being used as a biomarker for structural and functional attributes of the brain. Furthermore, the findings can provide new insights into mechanisms of disease and aging of the brain

APOE

aging

atrophy

brain

cognition

cortisol

depression

hippocampus

HPA axis

MRI

stress

telomere length

white matter hyper-intensities.

Cellular and Molecular Mechanisms Underlying Acute Quadriplegic Myopathy : Studies in Experimental Animal Models and Intensive Care Unit Patients

Norman, Holly

January 2006

The combination of a severe systemic illness, corticosteroids, and neuromuscular blocking agents in patients on the mechanical ventilator often results in a condition known as Acute Quadriplegic Myopathy (AQM). While severe weakness of all spinal nerve innervated muscles is known to be a significant clinical characteristic of the disease, this symptom is typically not recognized until the disease has progressed to an advanced stage. End result effects have been classified, which include the loss of the thick filament, or myosin heavy chain, an in-excitable muscle membrane, and an up-regulation of protein degradation; however, there is little known about the acute stage of AQM. This project has focused on understanding the underlying mechanisms of AQM, specifically in regard to protein synthesis, both at the mRNA and nuclear transcription levels. To study the early stages of the disease two animal models have been developed: rat and pig. Further, we have examined AQM muscle tissue, to investigate the similarities of our animal models to patients, as well as to study the recovery process. Particular interest was directed on the myofibrillar proteins myosin (MyHC) and actin, as they are the primary proteins involved in muscle contraction, as well as the myosin associated proteins, myosin binding protein C and H. At the mRNA level, MyHC and actin are both down-regulated in response to AQM. The myosin binding proteins are affected differently, with H protein increasing during severe atrophy and C protein either being slightly down-regulated or unchanged. Nuclear transcription factors were also affected, with such factors as MuRF1 and MAFbx up-regulated. Thus far results have shown that protein synthesis is altered in AQM and largely contributes to both the development and recovery of the disease. The pathways of protein synthesis may prove to be an ideal target for the prevention of AQM and/or symptom alleviation.

Neurosciences

Acute Quadriplegic Myopathy

intensive care unit

atrophy

myosin heavy chain

actin

myosin binding proteins

nuclear transcription factors

mRNA

Neurovetenskap

Nuclear medicine methods in idiopathic Parkinsonism : pre- and postsynaptic dopamine SPECT / Nuklearmedicinska metoder vid idiopatisk Parkinsonism : pre- och postsynaptisk dopamin SPECT

Jakobson Mo, Susanna

January 2013

Background: Single photon emission computed tomography (SPECT) with dopamine transporter (DAT) and dopamine D2 receptor (D2R) ligands can visualise the integrity of the nigrostriatal dopamine system. Parkinson’s disease (PD) and the atypical parkinsonian diseases (APD), progressive supranuclear palsy (PSP) and multiple system atrophy (MSA), have similar symptoms and dopamine depletion, but differ in pharmacological response and prognosis. Clinical differentiation between PD and APD is often difficult in the early stages. The aims of the thesis were to evaluate the differential diagnostic and prognostic value of SPECT in early PD, MSA and PSP, to map the pattern of progression with dopamine SPECT, and map the pattern of dopamine SPECT in non-affected elderly volunteers with a prospective approach. Also, we evaluated the methodological aspects of dopamine SPECT with respect to image evaluation tools, reconstruction parameters and gamma cameras. Methods: 172 patients, included in an on-going clinical prospective study on idiopathic parkinsonism, participated in the SPECT study. Also, 31 age-matched healthy controls (HC) were followed within this study. SPECT was done with 123I-FP-Cit (DAT SPECT) and 123I-IBZM (D2R SPECT). Regions of interest (ROI) were used as a standard method for semi-quantitative image analysis. Results: SPECT uptake ratios from different gamma cameras could be equalised through correction equations derived from images of a brain-like phantom, provided that attenuation correction was applied. The ROI method had high reproducibility. SPECT uptake  in HC, measured with the ROI method and a volume based (VOI) method rendered similar trends, but gender and age differences in SPECT uptake were more marked with the VOI method, and less pronounced in DAT SPECT compared to D2R SPECT with both methods. The DAT SPECT uptake was significantly reduced in very early disease stage of PD and APD compared to HC. DATSPECT uptake was more reduced in PD with postural and gait disturbance (PIGD) compared to tremor-dominant PD. Decline in DAT SPECT uptake during the first year was more pronounced in PD and PSP compared to HC. D2R SPECT uptake overlapped between untreated PD and APD. After initiated treatment, the D2R SPECT uptake was significantly higher in MSA patients compared to PD, PSP and HC. Decline in D2R SPECT uptake during the first year was not significantly different between patients or compared to HC. Conclusions: 123I-FP-Cit SPECT is a valuable and sensitive method to detect early stage idiopathic parkinsonism. A different level of uptake between PIGD-PD compared to TD-PD indicates a prognostic potential. It is not possible to differ between PD, MSA and PSP in early stage with 123I-FP-Cit SPECT and no differential diagnostic value was found using 123I-IBZM SPECT in the early, untreated stage of PD, MSA and PSP. A different pattern of uptake of this ligand in MSA compared to PD and PSP during the first years of L-dopa treatment may, however, indicate a diagnostic value during the follow-up period.

Nuclear medicine

SPECT

123I-FP-Cit

123I-IBZM

dopamine

parkinsonism

Parkinson’s disease

multiple system atrophy

progressive supranuclear palsy

Identification and Characterization of an Arginine-methylated Survival of Motor Neuron (SMN) Interactor in Spinal Muscular Atrophy (SMA)

Tadesse, Helina

19 December 2012

Spinal Muscular Atrophy (SMA) is a neuronal degenerative disease caused by the mutation or loss of the Survival Motor Neuron (SMN) gene. The cause for the specific motor neuron susceptibility in SMA has not been identified. The high axonal transport/localization demand on motor neurons may be one potentially disrupted function, more specific to these cells. We therefore used a large-scale immunoprecipitation (IP) experiment, to identify potential interactors of SMN involved in neuronal transport and localization of mRNA targets. We identified KH-type splicing regulatory protein (KSRP), a multifunctional RNA-binding protein that has been implicated in transcriptional regulation, neuro-specific alternative splicing, and mRNA decay. KSRP is closely related to chick zipcode-binding protein 2 and rat MARTA1, proteins involved in neuronal transport/localization of beta-actin and microtubule-associated protein 2 mRNAs, respectively. We demonstrated that KSRP is arginine methylated, a novel SMN interactor (specifically with the SMN Tudor domain; and not with SMA causing mutants). We also found this protein to be misregulated in the absence of SMN, resulting in increased mRNA stability of KSRP mRNA target, p21cip/waf1. A role for SMN as an axonal chaperone of methylated RBPs could thus be key in SMA pathophysiology.

Spinal Muscular Atrophy (SMA)

Survival Motor Neuron (SMN)

Neurodegenerative Disease

Arginine Methylation

Depression after stroke

Åström, Monica

January 1993

Both stroke and depression are major health problems in the elderly. In this study, the prevalence of major depression after stroke was investigated in a well-defined sample of acute stroke patients (n=80), followed up at 3 months, 1 year, 2 and 3 years after the stroke event. Links to biological and psychosocial factors were examined. Hypercortisolism was studied by the dexamethasone suppression test and compared with healthy elderly. Living conditions (including demographic caracteristics, economic resources, health, functional ability, activity/leisure, social network) and life satisfaction were described before and after stroke in relation to a general elderly population. Demographic caracteristics, economic resources, social network and psychiatric morbidity prestroke did not differ from the general elderly population. Already prior to the stroke, patients reported more health problems and lower functional ability in many aspects of daily life, more passive leisure time and a lower global life satisfaction. After stroke, contacts with children were maintained, whilst contacts outside the family declined and remained lower than in the general elderly population. Stroke involved a marked reduction in global life satisfaction. Poor life satisfaction at 1 year remained poor for the entire three years; these stroke victims had a higher frequency of major depression early after stroke. The prevalence of major depression was 25% at the acute stage, 31% at 3 months, decreased to 16% at 1 year, was 19% at 2 years and increased to 29% at 3 years. The most important predictors of immediate major depression were left anterior brain lesion, dysphasia, and living alone. Dependence in self-care ability and loss of social contacts outside the family were the most important predictors at 3 months. From 1 year onwards, loss of social contacts contributed most to depression and at 3 years also cerebral atrophy. Sixty percent of patients with early depression (0-3 months) had recovered at 1 year; those not recovered at 1 year had a high risk of chronicitation. Hypercortisolism as measured by the dexamethasone suppression test was associated with major depression late (3 years) but not early (0-3 months) after stroke. At 3 years, the dexamethasone suppression test had a sensitivity of 70%, a specificity of 97%, a positive predictive value of 88%, a negative predicitive value of 91%, and a diagnostic accuracy of 90%. Nonsuppression of dexamethasone at 3 months was a significant predictor of major depression at 3 years. / <p>Härtill 5 uppsatser</p> / digitalisering@umu

Cerebrovascular disorders

stroke

depression

living conditions

life satisfaction

social network

dysphasia

self-care ability

cerebral atrophy

dexamethasone

Identification and Characterization of an Arginine-methylated Survival of Motor Neuron (SMN) Interactor in Spinal Muscular Atrophy (SMA)

Tadesse, Helina

19 December 2012

Spinal Muscular Atrophy (SMA) is a neuronal degenerative disease caused by the mutation or loss of the Survival Motor Neuron (SMN) gene. The cause for the specific motor neuron susceptibility in SMA has not been identified. The high axonal transport/localization demand on motor neurons may be one potentially disrupted function, more specific to these cells. We therefore used a large-scale immunoprecipitation (IP) experiment, to identify potential interactors of SMN involved in neuronal transport and localization of mRNA targets. We identified KH-type splicing regulatory protein (KSRP), a multifunctional RNA-binding protein that has been implicated in transcriptional regulation, neuro-specific alternative splicing, and mRNA decay. KSRP is closely related to chick zipcode-binding protein 2 and rat MARTA1, proteins involved in neuronal transport/localization of beta-actin and microtubule-associated protein 2 mRNAs, respectively. We demonstrated that KSRP is arginine methylated, a novel SMN interactor (specifically with the SMN Tudor domain; and not with SMA causing mutants). We also found this protein to be misregulated in the absence of SMN, resulting in increased mRNA stability of KSRP mRNA target, p21cip/waf1. A role for SMN as an axonal chaperone of methylated RBPs could thus be key in SMA pathophysiology.

Spinal Muscular Atrophy (SMA)

Survival Motor Neuron (SMN)

Neurodegenerative Disease

Arginine Methylation

Old-age muscle atrophy: cellular mechanisms and behavioral consequences : an experimental study in the rat /

Altun, Mikael,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 5 uppsatser.

Implication de la protéine kinase AMP-dépendante dans le contrôle de la masse musculaire : régulation de l’autophagie / Implication of AMP-activated protein kinase in the control of skeletal muscle mass : regulation of autophagy.

Sanchez, Anthony

10 January 2012

Le contrôle de la masse musculaire est sous la dépendance d'un équilibre entre les processus de synthèse et de dégradation. Sur le plan cellulaire, deux voies signalétiques majeures sont impliquées : la voie des facteurs de transcription de la famille FoxO qui contrôle l'expression des gènes impliqués dans les systèmes de dégradation (système ubiquitine-protéasome et autophagie), et la voie IGF-1/Akt/mTORC1 qui représente la voie majeure de la synthèse protéique. Nos travaux mettent en évidence, sur des cellules musculaires le rôle de la protéine kinase AMP-dépendante (AMPK) qui inhibe l'activité de la voie mTOR et régule les systèmes ubiquitine-protéasome et autophagiques de manière FoxO3 dépendante. Une nouvelle cible de l'AMPK a également été identifiée : la protéine Ulk1 qui possède une fonction clé dans l'activation de l'autophagie. Par ailleurs, nous avons montré le rôle centraldu facteur d'initiation à la traduction eIF3f dans l'induction de l'hypertrophie, et dans l'augmentation de l'activité de la voie mTORC1 associée. De plus, nous montrons que la surexpression d'un mutant d'eIF3f résistant à la dégradation est associée à une protection effective contre l'atrophie. / Skeletal muscle mass is depending upon a dynamic balance between anabolic and catabolic processes. At a cellular level, two major signaling pathways are involved: the transcription factors FoxO related pathway, implicated in the control of protein breakdown systems(ubiquitin-proteasome system and autophagy), and the IGF-1/Akt/mTORC1 pathway associated with the canonic pathway of protein synthesis. We show in muscle cells that theAMP-activated protein kinase (AMPK) decreases the mTORC1 pathway activity and simulate subiquitin-proteasome and autophagy systems in a FoxO3-dependant manner. Furthermore,we identify Ulk1 as a new interacting partner of AMPK, which plays a major role in the autophagy induction. Moreover, we demonstrate the key role of the eukaryotic translation initiation factor eIF3f in hypertrophy induction and in the associated increase of the mTORC1activity. In addition, we show that the overexpression of an eIF3f mutant resistant to the degradation is associated with a protection against muscle atrophy.

AMP kinase

Aicar

Autophagie

Muscle squelétique

Protéolyse

Atrophie

AMP-activated protein kinase

Aicar

Autophagy

Skeletal muscle

Proteolysis

Atrophy